Example #1
0
    def send_goal(self, order):
        goal_msg = Fibonacci.Goal()
        goal_msg.order = order

        self._action_client.wait_for_server()

        return self._action_client.send_goal_async(goal_msg)
    def test_action_client_timeout(self):
        node = rclpy.create_node('simple_action_test')
        node.get_logger().set_level(rclpy.logging.LoggingSeverity.DEBUG)
        executor = SingleThreadedExecutor()

        def spin():
            rclpy.spin(node, executor=executor)

        """Test simple action state server timeout"""
        sm = StateMachine(['succeeded', 'aborted', 'preempted'])

        with sm:
            # Test single goal policy
            StateMachine.add(
                'GOAL_STATIC',
                SimpleActionState(
                    node,
                    "reference_action_not_available",
                    Fibonacci,
                    goal=Fibonacci.Goal(order=1),
                    server_wait_timeout=rclpy.time.Duration(seconds=10.0)))

        spinner = threading.Thread(target=spin)
        spinner.start()
        sq_outcome = sm.execute()
Example #3
0
    def send_goal(self, order):
        goal_msg = Fibonacci.Goal()
        goal_msg.order = order

        self._action_client.wait_for_server()

        self._send_goal_future = self._action_client.send_goal_async(goal_msg)

        self._send_goal_future.add_done_callback(self.goal_response_callback)
Example #4
0
    def send_goal(self, order):
        # Cancel timer and send an action goal only once
        self.timer.cancel()

        # Wait for action server
        self.action_client_.wait_for_server()

        # Define a action goal
        goal_msg = Fibonacci.Goal()
        goal_msg.order = order

        # Call send_goal_async() method
        self.send_goal_future = self.action_client_.send_goal_async(
            goal_msg, feedback_callback=self.feedback_callback)
        self.send_goal_future.add_done_callback(self.goal_response_callback)
#!/usr/bin/env python3
import rclpy
from rclpy.executors import SingleThreadedExecutor, MultiThreadedExecutor

import unittest
import threading

from smach import *
from smach_ros import *
from smach_msgs.msg import *

# Static goals
from action_tutorials_interfaces.action import Fibonacci
g1 = Fibonacci.Goal(order=1)
g2 = Fibonacci.Goal(order=2)


### Custom state classe
class Setter(RosState):
    """State that sets the key 'a' in its userdata"""
    def __init__(self, node):
        RosState.__init__(self, node, outcomes=['done'], output_keys=['a'])

    def execute(self, ud):
        ud.a = 'A'
        self.node.get_logger().info("Added key 'a'.")
        return 'done'


class Getter(RosState):
    """State that grabs the key 'a' from userdata, and sets 'b'"""
#!/usr/bin/env python3
import rclpy
from rclpy.executors import SingleThreadedExecutor, MultiThreadedExecutor

import unittest
import threading

from smach import *
from smach_ros import *
from smach_msgs.msg import *

from action_tutorials_interfaces.action import Fibonacci

# Static goals
g1 = Fibonacci.Goal(order=1)  # This goal should succeed


### Test harness
class TestSequence(unittest.TestCase):
    def test_sequence(self):
        """Test adding a sequence of states."""
        node = rclpy.create_node('sequence_test')
        node.get_logger().set_level(rclpy.logging.LoggingSeverity.DEBUG)
        executor = SingleThreadedExecutor()

        def spin():
            rclpy.spin(node, executor=executor)

        sq = Sequence(['succeeded', 'aborted', 'preempted', 'done'],
                      connector_outcome='succeeded')
        with sq:
Example #7
0
 def goal_cb_0(ud, default_goal):
     return Fibonacci.Goal(order=1)
Example #8
0
    def test_action_client(self):
        """Test simple action states"""
        node = rclpy.create_node('simple_action_test')
        node.get_logger().set_level(rclpy.logging.LoggingSeverity.DEBUG)
        executor = SingleThreadedExecutor()

        def spin():
            rclpy.spin(node, executor=executor)

        sq = Sequence(['succeeded', 'aborted', 'preempted', 'foobar'],
                      'succeeded')

        sq.userdata['g1'] = g1
        sq.userdata['g2'] = g2
        sq.userdata['order'] = 1
        sq.userdata['goal_alias'] = 1

        with sq:
            # Test single goal policy
            Sequence.add(
                'GOAL_STATIC',
                SimpleActionState(node, "fibonacci", Fibonacci, goal=g1))
            Sequence.add(
                'GOAL_KEY',
                SimpleActionState(node, "fibonacci", Fibonacci, goal_key='g1'))
            Sequence.add(
                'GOAL_SLOTS',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal_slots=['order']))
            Sequence.add('GOAL_SLOTS_REMAP',
                         SimpleActionState(node,
                                           "fibonacci",
                                           Fibonacci,
                                           goal_slots=['order']),
                         remapping={'order': 'goal_alias'})

            # Test goal callback
            def goal_cb_0(ud, default_goal):
                return Fibonacci.Goal(order=1)

            Sequence.add(
                'GOAL_CB',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal_cb=goal_cb_0))
            Sequence.add(
                'GOAL_CB_LAMBDA',
                SimpleActionState(
                    node,
                    "fibonacci",
                    Fibonacci,
                    goal_cb=lambda ud, goal: Fibonacci.Goal(order=1)))
            Sequence.add(
                'GOAL_CB_UD',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal_cb=lambda ud, goal: ud.g1,
                                  input_keys=['g1']))

            @cb_interface(input_keys=['g1'])
            def goal_cb_1(ud, default_goal):
                return ud.g1

            Sequence.add(
                'GOAL_CB_UD_DECORATOR',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal_cb=goal_cb_1))
            Sequence.add(
                'GOAL_CB_ARGS',
                SimpleActionState(
                    node,
                    "fibonacci",
                    Fibonacci,
                    goal_cb=lambda ud, goal, g: Fibonacci.Goal(order=g),
                    goal_cb_args=[1]))
            Sequence.add(
                'GOAL_CB_KWARGS',
                SimpleActionState(
                    node,
                    "fibonacci",
                    Fibonacci,
                    goal_cb=lambda ud, goal, gg: Fibonacci.Goal(order=gg),
                    goal_cb_kwargs={'gg': 1}))
            Sequence.add(
                'GOAL_CB_ARGS_KWARGS',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal_cb=lambda ud, goal, g, gg: Fibonacci.
                                  Goal(order=(g - gg)),
                                  goal_cb_args=[2],
                                  goal_cb_kwargs={'gg': 1}))

            # Test overriding goal policies
            Sequence.add(
                'GOAL_STATIC_SLOTS',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal=g2,
                                  goal_slots=['order']))
            Sequence.add(
                'GOAL_STATIC_CB',
                SimpleActionState(
                    node,
                    "fibonacci",
                    Fibonacci,
                    goal=g2,
                    goal_cb=CBInterface(
                        lambda ud, goal: setattr(goal, 'order', 1),
                        output_keys=['goal'])))

            # Test result policies
            Sequence.add(
                'RESULT_KEY',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal=g1,
                                  result_key='res_key'))
            Sequence.add('RESULT_KEY_CHECK', AssertUDState(['res_key']))

            Sequence.add(
                'RESULT_CB',
                SimpleActionState(
                    node,
                    "fibonacci",
                    Fibonacci,
                    goal=g1,
                    result_cb=CBInterface(
                        lambda ud, res_stat, res: setattr(ud, 'res_cb', res),
                        output_keys=['res_cb'])))
            Sequence.add('RESULT_CB_CHECK', AssertUDState(['res_cb']))

            Sequence.add(
                'RESULT_SLOTS',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal=g1,
                                  result_slots=['sequence']))
            Sequence.add('RESULT_SLOTS_CHECK', AssertUDState(['sequence']))

            Sequence.add('RESULT_SLOTS_REMAP',
                         SimpleActionState(node,
                                           "fibonacci",
                                           Fibonacci,
                                           goal=g1,
                                           result_slots=['sequence']),
                         remapping={'sequence': 'res_alias'})
            Sequence.add('RESULT_SLOTS_MAP_CHECK',
                         AssertUDState(['res_alias']))

            Sequence.add(
                'RESULT_CB_OUTCOME',
                SimpleActionState(node,
                                  "fibonacci",
                                  Fibonacci,
                                  goal=g1,
                                  result_cb=CBInterface(
                                      lambda ud, res_stat, res: 'foobar',
                                      outcomes=['foobar'])))

        spinner = threading.Thread(target=spin)
        spinner.start()
        sq_outcome = sq.execute()
        assert sq_outcome == 'foobar'
Example #9
0
#!/usr/bin/env python3
import rclpy
from rclpy.executors import SingleThreadedExecutor, MultiThreadedExecutor

import unittest
import threading
import traceback

from action_tutorials_interfaces.action import Fibonacci

from smach import *
from smach_ros import *
from smach_msgs.msg import *

# Static goals
g1 = Fibonacci.Goal(order=1)  # This goal should succeed
g2 = Fibonacci.Goal(order=2)  # This goal should abort
g3 = Fibonacci.Goal(order=3)  # This goal should be rejected


class AssertUDState(State):
    def __init__(self, keys):
        State.__init__(self, outcomes=['succeeded', 'aborted'])
        self._keys = keys
        self.register_input_keys(keys)

    def execute(self, ud):
        for key in self._keys:
            if key not in ud:
                print("Key '%s' not in userdata. Available keys are: %s" %
                      (key, ud.keys()))